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Abstract
Plasticity in the subcortical motor basal ganglia-thalamo-cerebellar network plays a key role in the acquisition and control of long-term memory for new procedural skills, from the formation of population trajectories controlling trained motor skills in the striatum to the adaptation of sensorimotor maps in the cerebellum. However, recent findings demonstrate the involvement of a wider cortical and subcortical brain network in the consolidation and control of well-trained actions, including of a brain region traditionally associated with declarative memory - the hippocampus. Here, we probe which role these subcortical areas play in skilled motor sequence control, from sequence feature selection during planning to their integration during sequence execution. An fMRI dataset (N=24, 14 female) collected after participants learnt to produce four finger press sequences entirely from memory with high movement and timing accuracy over several days was examined for both changes in BOLD activity and their informational content in subcortical regions of interest. Although there was a widespread activity increase in effector-related striatal, thalamic and cerebellar regions, in particular during sequence execution, the associated activity did not contain information on the motor sequence identity. In contrast, hippocampal activity increased during planning and predicted the order of the upcoming sequence of movements. Our findings suggests that the hippocampus pre-orders movements for skilled action sequences, thus contributing to the higher-order control of skilled movements that require flexible retrieval. These findings challenge the traditional taxonomy of episodic and procedural memory and carry implications for the rehabilitation of individuals with neurodegenerative disorders. Significance statement Skilled actions like handwriting, typing, and playing music, involve recombining movements into various sequences and producing them from memory. This fMRI study suggests that the hippocampus, traditionally associated with episodic memory and spatial navigation, pre-orders well-trained movement sequences prior to their execution. These findings challenge the canonical separation between episodic and procedural memory systems and the neural basis of skilled motor behaviours.
Original language | English |
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Article number | e0832242024 |
Journal | The Journal of Neuroscience |
Early online date | 24 Sept 2024 |
DOIs | |
Publication status | E-pub ahead of print - 24 Sept 2024 |
Bibliographical note
Copyright © 2024 Yewbrey and Kornysheva.Projects
- 1 Active
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Neural basis of sequence planning in motor coordination disorders
THE ACADEMY OF MEDICAL SCIENCES
1/12/21 → 1/12/24
Project: Research